Methods for producing and dispensing chilled water

ABSTRACT

A representative method for producing and dispensing chilled water includes: receiving, by a stand-alone apparatus, a flow of water; filtering, within the stand-alone apparatus, the flow of water to produce filtered water; producing, within the stand-alone apparatus, ice from a first portion of the filtered water; cooling, within the stand-alone apparatus, a second portion of the filtered water with the ice to form chilled water in response to a user input corresponding to a request for chilled water; and dispensing the chilled water from the stand-alone apparatus in accordance with the user input.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a Continuation of U.S. application Ser. No.16/504,690, filed on Jul. 8, 2019, the entirety of which is incorporatedby reference herein.

BACKGROUND

Bottled water typically is purified in some manner and bottled for salein predetermined increments of volume. The bottled water then is shippedto multiple points of sale and often refrigerated prior to use. Thispractice of centralized manufacture followed by distribution leads to ahuge disposal problem with plastic water bottles and associatedpackaging.

Current trends for providing water involve various attempts to reusewater bottles, such as is facilitated by water filling stations.Unfortunately, providing an adequate volume of chilled water has provenchallenging as refrigeration systems of water filling stations tend tostore a relatively limited volume of chilled water that, once dispensed,is difficult to replenish due to slow volumetric cooling rates.

Thus, there exists a need to address these and/or other perceivedshortcomings of the prior art.

SUMMARY

Broadly stated, the present disclosure is concerned with systems andmethods for producing and dispensing chilled water. In at least oneembodiment, such a system comprises: an exterior housing defining aninterior compartment; a water tank disposed within the interiorcompartment; a filtration system, disposed within the interiorcompartment, configured to receive a flow of water from outside theexterior housing, filter the flow of water and provide filtered water tothe water tank; an ice maker, disposed within the interior compartmentand along a first flow path from the water tank, configured to produceice from the filtered water provided from the first flow path; an icebin, disposed within the interior compartment, configured to receive theice from the ice maker; a user interface configured to receive a userinput corresponding to a request for chilled water; a water controlvalve, disposed within the interior compartment and along a second flowpath from the water tank, configured to receive the filtered waterprovided from the second flow path and provide a controlled flow of thefiltered water to the ice bin in response to the user input such thatthe controlled flow of the filtered water is cooled by the ice in theice bin to form chilled water; and a water dispenser fluidlycommunicating with the ice bin and configured to provide the chilledwater outside of the exterior housing according to the user input.

In some embodiments, the filtration system has a reverse osmosis (RO)filter assembly and a pre-RO filter assembly; the pre-RO filter assemblyis configured to receive the flow of water, reduce particulate contentfrom the flow of water and provide pre-RO filtered water to the ROfilter assembly; the RO filter assembly has an RO pump and a first ROmembrane assembly; and the RO pump is configured to receive the pre-ROfiltered water and direct the pre-RO filtered water to the first ROmembrane assembly, which filters the pre-RO filtered water and providesthe filtered water to the water tank.

In some embodiments, the RO filter assembly has a second RO membraneassembly fluidly communicating in series with the first RO membraneassembly.

In some embodiments, the pre-RO filter assembly has a sediment filter.

In some embodiments, the pre-RO filter assembly further has a carbonfilter fluidly communicating in series with the sediment filter.

In some embodiments, an ultraviolet (UV) filter, disposed along thefirst flow path and the second flow path, is configured to furtherfilter the filtered water provided from the water tank.

In some embodiments, a pre-demand pump, disposed along the first flowpath and the second flow path, is configured to provide a pressurizedflow of the filtered water from the water tank.

In some embodiments, a flavor delivery assembly is configured toselectively provide a flavoring agent to the chilled water.

In some embodiments, the water dispenser has a first chilled wateroutlet configured to dispense the chilled water and a second chilledwater outlet configured to receive the flavoring agent from the flavordelivery assembly and dispense the chilled water with the flavoringagent.

In at least one embodiment, such a method comprises: receiving, by astand-alone apparatus, a flow of water; filtering, within thestand-alone apparatus, the flow of water to produce filtered water;producing, within the stand-alone apparatus, ice from a first portion ofthe filtered water; cooling, within the stand-alone apparatus, a secondportion of the filtered water with the ice to form chilled water inresponse to a user input corresponding to a request for chilled water;and dispensing the chilled water from the stand-alone apparatus inaccordance with the user input.

In some embodiments, the filtering comprises performing reverse osmosison the flow of water.

In some embodiments, the filtering further comprises performing sedimentfiltering prior to the reverse osmosis.

In some embodiments, the method further comprises subjecting the firstportion and the second portion of the filtered water to ultravioletlight filtering.

In some embodiments, the method further comprises selectively providinga flavoring agent to the chilled water.

In some embodiments, the cooling comprises directing the second portionof the filtered water to an ice bin containing the ice.

Additional objects and/or advantages may become apparent to thoseskilled in the art from the following detailed description, accompanyingdrawings and claims.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic view of example embodiment of a system forproducing and dispensing chilled water.

FIG. 2 is a flowchart of an example embodiment of a method for producingand dispensing chilled water.

FIG. 3A is perspective view of another example embodiment of a systemfor producing and dispensing chilled water.

FIG. 3B is perspective view of the embodiment of FIG. 1A with the doorin an open position.

FIGS. 4A-4D are schematic elevational views of the embodiment of FIGS.3A and 3B.

FIG. 5 is a schematic view of the embodiment of FIGS. 3A, 3B and 4A-4D.

FIG. 6 is a schematic elevational view of the embodiment of FIG. 5.

FIG. 7 is schematic view shown partially in cross-section as viewedalong section line A-A of FIG. 6.

FIG. 8 is a schematic elevational view of the embodiment of FIGS. 6 and7.

FIG. 9 is schematic view shown partially in cross-section as viewedalong section line B-B of FIG. 8.

FIG. 10 is a schematic elevational view of the embodiment of FIGS. 6-9.

FIG. 11 is schematic view shown partially in cross-section as viewedalong section line C-C of FIG. 10.

FIG. 12 is schematic view shown partially in cross-section as viewedalong section line D-D of FIG. 10.

DETAILED DESCRIPTION

For ease in explanation, the following discussion describes severalembodiments of systems and methods for producing and dispensing chilledwater. It is to be understood that the invention is not limited in itsapplication to the details of the particular arrangements shown sincethe invention is capable of other embodiments. Also, the terminologyused herein is for the purpose of description and not of limitation.

As will be described in detail, various embodiments of systems andmethods for producing and dispensing chilled water involve the use of astand-alone apparatus that is configured to produce filtered water, someof which is used to form ice. A remainder of the filtered water isdirected to flow over the ice to produce chilled water, which is madeavailable for on-demand dispensing such as into a container provided bya consumer. Notably, the chilled water is produced in response to a userinput corresponding to a request for chilled water. As such, a readysupply of ice is maintained for cooling water and water is directed toflow over the stored ice only after a request for chilled water isreceived. This is in contrast to systems that exhibit inefficiencies byattempting to maintain a quantity of chilled water on-hand fordispensing.

In this regard, FIG. 1 depicts an example embodiment of a system forproducing and dispensing chilled water. In particular, system 100 isconfigured as a stand-alone apparatus that merely requires water andpower hook-ups and, in some embodiments, a communications interface(s)(for example, to facilitate electronic payment, system monitoring,etc.). System 100 incorporates an exterior housing 102 that defines aninterior compartment 104. Various subsystems/components are disposedwithin interior compartment 104, including a water tank 106, afiltration system 108, an ice maker 110, an ice bin 112, a water controlvalve 114, and a water dispenser 116.

Filtration system 108 is configured to receive a flow of water fromoutside exterior housing 102, such as from a water line. Filtrationsystem 108 is further configured to filter the flow of water and providefiltered water to water tank 106. Downstream of water tank 106, thefiltered water is routed as needed along a first flow path 118 and asecond flow path 120. Specifically, filtered water routed along firstflow path 118 is provided to ice maker 110 to produce ice, which isdeposited into ice bin 112 for storage.

Filtered water routed along second flow path 120 is provided, viaoperation of water control valve 114, to ice bin 112 so that thefiltered water is cooled by the stored ice to form chilled water, whichexhibits a temperature slightly above the freezing temperature (32° F.or 0° C.). The chilled water is produced in response to a user inputcorresponding to a request for chilled water such as may be provided viainteraction with a user interface 115. In some embodiments, the userinput is used to direct water control valve 114 to provide an adequateamount of filtered water is directed along second flow path 120 to icebin 112 for cooling. Additionally, the user input may be used to controldispensing of an adequate amount of chilled water from ice bin 112 bywater dispenser 116 to meet the user request.

Water dispenser 116 fluidly communicates with ice bin 112 and isconfigured to dispense the chilled water outside of exterior housing102. Dispensing of the chilled water may be performed in pre-programmedamounts or consumer-selected amounts according to the user input. Thedispensed amounts may be set in common sizes, pints, quarts, and/orliters, for example. By way of example, if a user desired 16 ounces ofchilled water, the user may interact with user interface 115 so that auser input in the form of a demand signal is provided corresponding to16 ounces. In response to the demand signal, water control valve 114directs an adequate amount of filtered water (e.g., 16 ounces) to icebin 112 for cooling. As the water flows downwardly through the ice inice bin 112, the water is cooled an a portion of the ice may melt, thusthere may be more than 16 ounces of chilled water available at thebottom of ice bin 112 for dispensing. The user input then is used bywater dispenser 116 to ensure that 16 ounces of chilled water isdispensed.

In the embodiment of FIG. 1, an optional UV light filter 122 is provideddownstream of water tank 106 and upstream of the divergence of first andsecond flow paths 118 and 120. Filtered water from water tank 106 isexposed to ultraviolet (UV) light from UV light filter 122 to provide UVfiltered water for the production of ice in ice maker 110 and fordirecting to ice bin 112 for cooling prior to being dispensed.

FIG. 2 is a flowchart of an example embodiment of a method for producingand dispensing chilled water, such as may be performed by system 100,for example. As shown in FIG. 2, method 130 may be construed asbeginning at block 132, in which a flow of water is received by astand-alone apparatus. In block 134, the flow of water is filteredwithin the stand-alone apparatus to produce filtered water. In someembodiments, this may involve one or more of performing reverse osmosis,sediment filtering or ultraviolet light filtering on the flow of water.In block 136, ice is produced within the stand-alone apparatus from afirst portion of the filtered water, and (as depicted in block 138) asecond portion of the filtered water is cooled with the ice to formchilled water within the stand-alone apparatus in response to a userinput corresponding to a request for chilled water. Thereafter, such asdepicted in block 140, the chilled water is dispensed from thestand-alone apparatus in accordance with the user input. In someembodiments, this may additionally involve selectively providing aflavoring agent to the chilled water so that the chilled water mixeswith the flavoring agent.

FIGS. 3A, 3B, 4A-4D and 5-12 depict another example embodiment of asystem for producing and dispensing chilled water. As shown most clearlywith reference to FIGS. 3A and 3B, system 150 is configured as astand-alone apparatus that incorporates an exterior housing 152 definingan interior compartment 154. Various subsystems/components are disposedwithin interior compartment 154 that will be described in detail later.In this embodiment, a door 155, movable between a closed position (see,FIG. 3A) and an open position (see, FIG. 3B), provides access tointerior compartment 154 when in the open position.

As shown most clearly with reference to FIG. 4D, water, power andcommunications interconnects are provided. Specifically, waterinterconnect 156, drain interconnect 158, power interconnect 160 andcommunications interconnect 162 are provided. Additionally, system 150incorporates a payment station 164 (FIG. 4B) that is configured toaccept bills, coins, credit cards, and/or other forms of payment.Depending upon the configuration, payment station 164 may use powerand/or communications capabilities provided by power interconnect 160and communications interconnect 162, respectively, in order tofacilitate point-of-sale transactions associated with the dispensing ofchilled water.

Dispensing of the chilled water may be performed in pre-programmedamounts or consumer-selected amounts such as via interaction with a userinterface 166, which may be configured with a touchscreen for receivinguser inputs, in some embodiments. The inputs may be evaluated inaccordance with computer processor-executed instructions that are usedto determine an amount of chilled water that is to be dispensed. Thedispensed amounts may be set in common sizes, pints, quarts, and/orliters, for example. A water dispenser 168, which incorporates a movabledoor 170 in this embodiment for exposing a chilled water outlet, is usedto dispense the chilled water.

With reference to FIGS. 5-12, various subsystems/components of system150 will be described in greater detail. As shown in FIG. 5, waterinterconnect 156 fluidly communicates with backflow preventer 172, which(in cooperation with overfill control device 174) provides a flow ofwater to filtration system 176. Filtration system 176 is configured tofilter the flow of water and provide filtered water to a water tank 200.In particular, filtration system 176 includes a reverse osmosis (RO)filter assembly 178 and a pre-RO filter assembly 180. Pre-RO filterassembly 180 is configured to receive the flow of water, reduceparticulate content from the flow of water and provide pre-RO filteredwater to RO filter assembly 178.

In this embodiment, pre-RO filter assembly 180 includes a sedimentfilter 182 and a carbon filter 184 that are connected in series. Filters182 and 184 filter the flow of water and provide the pre-RO filteredwater to a reverse osmosis (RO) pump 186 of RO filter assembly 178. Alow pressure switch 188 monitors pressure of the flow of water providedto RO pump 186 and, in response to a low pressure condition, provides asignal to low pressure pump control 190 (e.g., a solenoid) to turn offRO pump 186 in order to prevent damage to the pump.

RO pump 186 directs a flow of water to one or more RO membraneassemblies. In this embodiment, three RO membrane assemblies (192, 194and 196) are provided that fluidly communicate in series. Each of the ROmembrane assemblies may include one or more RO membranes. Notably, waterprovided to an RO filter may be directed to drain via drain interconnect158 such as if an overfill condition is sensed, for example. Water notdirected to drain is provided as filtered water to water tank 200.

Downstream of water tank 200, the filtered water is provided topre-demand pump 202, after which the filtered water is exposed toultraviolet (UV) light from a UV light filter 204. From UV light filter204, the filtered water is routed as needed along a first flow path 206and a second flow path 208. Specifically, filtered water routed alongfirst flow path 206 is provided to ice maker 210 to produce ice, whichis deposited into ice bin 212 for storage. In this embodiment, anoptional current sensor 213 is shown that is electrically coupled to icemaker 212. Current sensor 213 is used to determine whether ice maker 212is operational and pulling current.

Ice bin 212 incorporates an inclined sidewall 211 that is configured todirect contents of ice bin 212 towards outlet 217, which is located at alow point of the bin. In this embodiment, sidewall 211 is positioned atthe rear of ice bin 212 and outlet 217 is located at the front; thus,sidewall 211 is inclined downwardly from back to front. It should alsobe noted that ice produced by ice maker 210 is dispensed into ice bintowards the rear of the bin and is urged forward by the slope ofsidewall 211.

Filtered water routed along second flow path 208 is provided, viaoperation of water control (bin) valve 214, to ice bin 212 so that thefiltered water is cooled by the stored ice to form chilled water. Valve214 directs an amount of filtered water into ice bin 212 in response toa demand signal, which corresponds to an input from user interface 166.In operation, such a user input may be interpreted by computerimplemented instructions (e.g., instructions 220) stored in memory 222and executed by processor 224 to generate the demand signal.

Processor 224 may include a custom made or commercially availableprocessor, a central processing unit (CPU) or an auxiliary processoramong several processors, a microprocessor, a semiconductor-basedmicroprocessor (in the form of a microchip), one or more applicationspecific integrated circuits (ASICs), a plurality of suitably configureddigital logic gates, and other electrical configurations comprisingdiscrete elements both individually and in various combinations tocoordinate the overall operation of the system.

Memory 224 can include any one or a combination of volatile memoryelements (e.g., random-access memory (RAM, such as DRAM, and SRAM,etc.)) and nonvolatile memory elements. The memory typically comprises anative operating system, one or more native applications, emulationsystems, or emulated applications for any of a variety of operatingsystems and/or emulated hardware platforms, emulated operating systems,etc. For example, the applications may include application specificsoftware which may comprise components associated with user interface166, payment station 164 and/or others. In accordance with suchembodiments, the components are stored in memory and executed byprocessor 224.

One of ordinary skill in the art will appreciate that the memory 224can, and typically will, comprise other components which have beenomitted for purposes of brevity. Note that in the context of thisdisclosure, a non-transitory computer-readable medium stores one or moreprograms for use by or in connection with an instruction executionsystem, apparatus, or device.

Water provided into ice bin 212 is distributed therein by a waterdistribution tube 226, which spans across a top portion of the bin.Water distribution tube 226 incorporates multiple outlet ports that areconfigured to distribute (e.g., spray) the water across a top surface ofthe ice stored in ice bin 212. In some embodiments, the outlet ports maybe arranged at an angle of inclination of approximately 30 degrees tocause the water to sprinkle over about 90% of the top surface of the icestored in the ice bin. As the water sprinkles over the ice, a portion ofthe ice melts and cools the water as the water flows down and arrives inthe vicinity of outlet 217. From there, the water is drawn through theoutlet 217 by suction provided by post-demand pump 244 for dispensing aschilled water, which may be flavored or unflavored in this embodiment.

By only distributing water into the ice bin for cooling in response toconsumer demand, a ready supply of ice is available for use andfreshness of the chilled water is maintained. Water remaining inside icebin 212 after consumer demand has been met and/or when the ice melts maybe purged out of the bin and used to rinse or clean dispensingcomponents of the system. Thus, the system is very efficient and is ableto maintain a full level of ice, which enables the system to deliverwhat may seem like an endless supply of chilled water.

Also shown is a temperature probe 215 that is configured to monitor thetemperature of the chilled water that is being dispensed. Informationfrom temperature probe 215 may also be used to determine whether icemaker 210 is operational since the water temperature tends to increaseas the amount of ice in ice bin 212 decreases. By way of example, if athreshold temperature of 35 degrees (F.) is set, in response totemperature probe 215 sensing a temperature above 35 degrees, an alarmindication may be actuated and/or the system may be disabled fromdispensing water until the desired temperature is achieved.

An overflow 216 is provided at a lower portion of ice bin 212 tofacilitate removal of excess chilled water. In some embodiments, this isaccomplished with the assistance of a sump pump 218 that urges excess todrain 158.

Water dispenser 168 fluidly communicates with ice bin 212 to receivechilled water. Water dispenser 168 incorporates a flow meter 242 and adownstream post-demand pump 244. Post-demand pump 244 operates bymonitoring a rate of flow of chilled water via flow meter 242 andprovides a requested amount of chilled water to be available at anappropriate chilled water outlet. In this embodiment, multiple chilledwater outlets are provided, with each being configured to perform adifferent function. By way of example, outlet 252, in cooperation withcontrol valve 253 (e.g., a solenoid), is configured to dispenseunflavored, chilled water to a consumer in amounts less than one gallon;whereas outlet 262, in cooperation with control valve 263, is configuredto dispense unflavored, chilled water to a consumer in amounts greaterthan one gallon. Additionally, outlet 254, in cooperation with controlvalves 255, 256 and 257, is configured to dispense flavored, chilledwater to a consumer. Specifically, each of the control valves 255, 256and 257 is configured to provide a predetermined amount of acorresponding flavoring agent (which is provided by flavor supply 260)based on user demand. Note that, in this embodiment, outlet 254 handlesall of the dispensed chilled water that receives flavoring agent so thatchilled water dispensed from outlet 252 remains free of any flavoringagent.

Purge valve 264 is configured to periodically purge (e.g., by means of asettable timer) water out of ice bin 212 to ensure that dispensedchilled water is fresh. This process, which functions in cooperationwith post-demand pump 244, also keeps water lines of water dispenser 168full of chilled water. Additionally, this process provides a rinsingfunction that prevents contamination of water-only components withflavor, as the purge operation flushes the water lines.

Thus, while particular embodiments have been shown and described indetail herein, various modifications may be made without departing fromthe scope of the present Invention or the appended claims.

What is claimed is:
 1. A method for producing and dispensing chilledwater comprising: receiving, by a stand-alone apparatus, a flow ofwater; filtering, within the stand-alone apparatus, the flow of water toproduce filtered water; producing, within the stand-alone apparatus, icefrom a first portion of the filtered water; cooling, within thestand-alone apparatus, a second portion of the filtered water with theice to form chilled water in response to a user input corresponding to arequest for chilled water; and dispensing the chilled water from thestand-alone apparatus in accordance with the user input.
 2. The methodof claim 1, wherein the filtering comprises performing reverse osmosison the flow of water.
 3. The method of claim 2, wherein the filteringfurther comprises performing sediment filtering prior to the reverseosmosis.
 4. The method of claim 1, further comprising subjecting thefirst portion and the second portion of the filtered water toultraviolet light filtering.
 5. The method of claim 1, furthercomprising selectively providing a flavoring agent to the chilled water.6. The method of claim 1, wherein the cooling comprises directing thesecond portion of the filtered water to an ice bin containing the ice.